KR19980018841A - DATA STORAGE APPARATUS EMPLOYING A MEMORY HAVING ONE OR MORE DATA STORAGE AREAS - Google Patents

Abstract

The data storage device comprises a flash memory having one or more image data storage areas, i.e., frames, with associated attribute data areas respectively corresponding to the image data storage areas in the device. Each attribute data storage area is used to store attribute data indicating the state of the corresponding image data storage area. The attribute data is (1) the image is stored in the image data storage area, or (2) the instruction to delete the image data from the data storage area is not yet executed, or (3) the data storage area is initialized. You can generally indicate that you are ready to record. Data in the image data storage area in the state indicative of the indeterminate deletion command is not deleted until the device is substantially turned on again for use. In this way, the effect of the long delay caused by the slow read-write time of the flash memory is minimized so that the user perceives the delay only at device startup.

Description

Data storage

The present invention relates to a data storage device, in particular a data storage device using memory data that does not allow overwriting, such as flash memory.

Recently developed digital still cameras generally use non-volatile flash memory that stores images captured by the camera. In the above digital still camera, a plurality of data storage areas are typically provided in a flash memory which respectively stores image data corresponding to an image taken in response to pressing a trigger switch on the camera. However, as is well known, data in flash memory cannot be directly overwritten; The memory must be initialized before new data can be written. Therefore, when new image data is to be stored in a data storage area that already contains the stored data, the camera must perform an initialization operation for deleting the original data before recording the new data in the storage area. Since this typically requires a long time of about 0.5 seconds, the operation time for storing image data in a data storage region that already contains other data is longer than the operation time for storing image data in an initialized data storage region. long. Since such a camera is designed to be prohibited from receiving additional input by the user during the operation time required to store the image data, the user recognizes that the camera is inoperable for such a relatively long time. Therefore, the longer the operation time for storing the image data, the smaller the perceived value of the camera. Alternatively, the user can press the delete key to initialize the frame rather than overwriting the data. However, the user often needs to delete a lot of frame off image data from the memory after the image has been printed or copied to another storage medium such as a hard disk. Since it takes about 0.5 to delete each, the long inoperation recognized during the deletion can be very inconvenient for the user.

It is therefore an object of the present invention to provide a data storage device in which the user is inoperable, i.e. minimizing or avoiding the recognition of down time during a period in which data is deleted from the storage device.

In order to achieve this object, the present invention provides a memory device comprising: memory means having one or more data storage areas for storing data; Operable recording means for recording data in a data storage area of said memory means; Operating means for operating the recording means to record data in the data storage area; Deletion instructing means for indicating a data storage area of said memory means to which stored data is to be deleted; Detection means for detecting a predetermined time when the operation means does not operate the recording means and during which it is desirable to delete data from the data storage area; There is provided a data storage device including deletion means for deleting data in the data storage area instructed by the deletion instructing means at a predetermined time detected by the detection means.

The invention also comprises memory means for storing one or more data sets; Recording means for recording a set of data in said memory means; Operating means for operating said recording means to record a set of data in said memory means; Deletion instructing means for indicating a set of data to be deleted from said memory means; Detection means for detecting a predetermined time at which the operation means is to be used the smallest for operating the recording means; And a deletion means for deleting the data set indicated by the deletion instruction means from the memory means at a predetermined time detected by the detection means. Although a preferred embodiment of the present invention is described with reference to a digital camera using a flash memory for storing an image, the present invention is useful for other devices using a flash memory or other nonvolatile memory as described herein.

1 is a block diagram of a digital still camera utilizing the present invention.

FIG. 2 is a flowchart showing the operation of the CPU 14 for the three basic operations of the electronic still camera shown in FIG.

3 is a flowchart showing an initialization operation by the CPU 14 in the second embodiment of the present invention.

4 is a flowchart showing an initialization operation by the CPU 14 in the third embodiment of the present invention.

Fig. 5 is a flowchart showing the initialization operation by the CPU 14 in the fourth embodiment of the present invention.

Fig. 5 is a flowchart showing the initialization operation by the CPU 14 in the fourth embodiment of the present invention.

Fig. 6 is a flowchart showing an initialization operation by the CPU 14 in the fifth embodiment of the present invention.

Fig. 7 is a flowchart showing the initialization operation by the CPU 14 in the sixth embodiment of the present invention.

8 is a flowchart showing an initialization operation by the CPU 14 in the seventh embodiment of the present invention.

9 is a flowchart showing an initialization operation by the CPU 14 in the eighth embodiment of the present invention.

Fig. 10 is a flowchart showing an initialization operation by the CPU 14 in the ninth embodiment of the present invention.

Fig. 11 is a flowchart showing the initialization operation by the CPU 14 in the tenth embodiment of the present invention.

12 is a flowchart showing the initialization operation by the CPU 14 in the eleventh embodiment of the present invention.

13 is a flowchart showing an initialization operation by the CPU 14 in the twelfth embodiment of the present invention.

Fig. 14 is a flowchart showing the initialization operation by the CPU 14 in the thirteenth embodiment of the present invention.

Fig. 15 is a flowchart showing the initialization operation by the CPU 14 in the fourteenth embodiment of the present invention.

Explanation of symbols for the main parts of the drawings

1: CCD 2,10: Amplifier 3: Analog-to-digital converter

4: timing controller 5: CDD driver 6: compression-decompression device

7: Signal Generator 8: VRAM 9: Digital-to-Analog Converter

11: Video output terminal 12: LCD 13: Key input device

14: CPU 15: ROM 16: RAM

17: DRAM 18: flash memory 19: serial input / output interface

20: serial input / output terminal

Hereinafter, preferred embodiments of the present invention will be described.

1 shows a block diagram of a digital still camera utilizing the present invention. A charge coupled device (CCD) 1 generates an electronic image signal based on an optical image focused on a surface through a well-known optical system (not shown) and supplies it to the amplifier 2. The amplifier 2 amplifies the electronic image signal and supplies it to the analog-to-digital converter (ADC) 3. The ADC 3 converts the electronic image signal amplified by the amplifier 2 into a digital image signal. The serial digital image signal output from the ADC 3 is supplied to the timing controller 4 and is converted into a parallel digital image by this 4. The timing controller 4 also supplies a timing signal to the CCD driver 5 that drives the CCD 1 under the control of the CPU (central processing unit) 14.

The CPU 14 controls the overall operation of the digital still camera to perform all functions in response to the information input from the key input device 13 and the program stored in the ROM 15. The RAM 16 is used as a work area of the CPU 14.

The key input device 13 selects one of a power switch for turning the camera on and off, a trigger switch for taking an image and storing image data corresponding to the image in a flash memory 18 which will be described later. A mode key for displaying, a playback key for displaying an image corresponding to the image data stored in the flash memory 18 on a display device such as the LCD 12 described later, and image data stored in the flash memory 18. And an image quality mode key for selecting one of a fine mode for taking an image having a high quality, a standard mode for taking an image having a standard quality, and other keys.

The dynamic random access memory (DRAM) 17 temporarily stores the parallel digital image signal output from the timing controller 4. The parallel digital image signal stored in the DRAM 17 is converted into a digital image signal composed of luminescence data and chroma data under the control of the CPU 14.

The digital image data is supplied to the compression-decompression device 6. The compression-decompression device 6 compresses parallel image data and supplies the compressed image data to the flash memory 18. The compression-decompression device 6 also decompresses the compressed image data supplied from the flash memory 18 and supplies the decompressed image data to the signal generator 7. The signal generator 7 produces a digital video signal based on the digital image signal supplied from the compression / decompression device 6 or the CPU 14. The digital video signal is supplied to a video random access memory (VRAM) 8 and a digital-to-analog converter (DAC) 9. The DAC 9 converts the digital video signal into an analog video signal. This analog signal is supplied to the video input terminal 11 and the LCD 12 via an amplifier 10. The LCD 12 displays an image based on the analog image signal.

The flash memory 18 has an image data storage area for storing compressed image data supplied from the compression-decompression device 6, and an attribute data storage area for storing attribute data for this image data storage area. In this embodiment, the flash memory 18 has 100 image data areas. Three image data storage areas in the flash memory 18 are required for storing compressed image data corresponding to the image taken in the fine mode. One image data storage area is required for storing compressed image data corresponding to an image taken in the standard mode. The flash memory 18 also has 100 attribute data storage areas respectively corresponding to the image data storage areas. Each attribute data storage area stores attribute data associated with each image data storage area. The attribute data indicates the state of the image data storage area. The attribute data 0 indicates an initialization state which means that the image data storage area is initialized and ready for recording. The attribute data 1 instructs the deletion state, which means that it has been input by the delete key in the key input device 13 to delete the image data in the image data storage area, but the command has not yet been executed. In other words, the data storage area has not yet been initialized. Attribute data 2 indicates a storage state which means that the image data storage area contains a stored image. The CPU 14 supplies the attribute data 0, 1 or 2 to the attribute data storage area of the flash memory 18 based on the information input from the key input device. It should be noted that in another embodiment of the present invention, the attribute data storage area may be a memory different from the flash memory.

The compressed image data stored in the flash memory 8 is supplied to the serial input / output terminal 20 via the CPU 14 and the serial input / output interface 19 as described above, as well as the compression-decompression device 6. It is also supplied to the signal generator 7 which has passed through). The serial input / output terminal 20 can be connected to something such as a personal computer.

Hereinafter, the operation of the electronic still camera will be described.

In the playback mode selected by the mode key of the key input device 13, the LCD 12 displays the object focused on the CCD 1. When the trigger switch of the key input device 13 is pressed, the CPU 14 performs an image capturing operation. Under the control of the CPU 14, the electronic image signal generated by the CCD 1 is supplied to the ADC 3 via the amplifier 2 and converted into a digital image signal. The digital image signal is supplied to the timing controller 4 and converted into a parallel image signal. Then, the parallel image signal is temporarily stored in the DRAM 17. The CPU 14 processes parallel image signals stored in the DRAM 17 to produce digital image data constituting the light emission data and the chroma data. The digital image data is supplied to the compression-decompression device 6 and compressed. The CPU 14 detects attribute data 0 stored in the attribute data storage area of the flash memory 18 and designates the address of the image data storage area corresponding to the attribute data storage area in which the attribute data 0 is stored. The compressed image data is then stored in the image data storage area S of the flash memory addressed to the CPU 14. In the fine mode selected by the image quality mode key of the key input device 13, the compressed image data is stored in three data image storage areas of the flash memory 18. On the other hand, when the standard mode is selected, the compressed image data is stored in one data image storage area of the flash memory 18. The CPU 14 supplies the attribute data 2 to the attribute data storage region corresponding to the image data storage region for storing the compressed image data.

When the playback key of the key input device 13 is pressed in the playback mode selected by the mode key, the CPU 14 performs an operation for displaying on the LCD 12 an image corresponding to the image data stored in the flash memory 18. . The CPU 14 detects attribute data 2 stored in the attribute data storage area of the flash memory 18. The CPU 14 designates the address of the image data storage area corresponding to the attribute data storage area storing data 2 for reading the image data from the flash memory 18. The CPU 14 performs an operation for searching for attribute data 2 stored in another attribute data storage area each time the play key is pressed. The image data read out from the flash memory 18 is supplied to the compression-decompression device 6 and decompressed. The decompressed image data is sent to the signal generator 7 and converted into a digital video signal. The digital video signal is supplied to the VRAM 8 and the digital analog converter (DAC) 9. The DAC 9 converts the digital video signal into an analog video signal and supplies it to the LCD 12 via the amplifier 10. The LCD 12 displays an image based on the analog video signal.

When the LCD 12 presses the delete key of the key input unit 13 while displaying an image based on an analog video signal in the playback mode, the CPU 14 causes the image data stored in the flash memory 18 corresponding to the displayed image. Perform the operation to delete the. The CPU 14 designates the address of the attribute data storage area corresponding to the image data storage area storing the image data of the displayed video and records the attribute data 1 in the addressed attribute data storage area.

2 shows the operation of the CPU 14, i.e., the initialization operation, the deletion operation, and the recording operation, for three basic operations of the electronic still camera.

When the electronic still camera is turned on by the power switch of the key input device 13, the CPU 14 determines whether there is an image data storage area of the flash memory 18 to be initialized (step A1). In other words, the CPU 14 checks the attribute data storage area of the flash memory 18 in which data 1 is stored. If the CPU 14 detects 1 in the attribute data storage area, the CPU 14 initializes the image data storage areas corresponding to these attribute data storage areas stored as data 1 and attributes the attribute data 1 in the attribute data storage area. Replace with data 0 (step A2).

The CPU 14 then checks which mode is selected from the recording mode or the reproduction mode by the mode key (step A3). As mentioned above, when the CPU 14 detects that the delete key of the key input unit is pressed in the playback mode (step A4), the attribute 14 stores the attribute data storage area corresponding to the image data storage area storing the image data to be deleted. Set to data 1 (step A5). Since the digital image data stored in the flash memory 18 is not deleted at this time, the erasing operation is completed in a relatively short time.

When the recording mode is pressed in the key input device 13 (step A6), the CPU 14 stores the digital image data in the image data storage area of the flash memory 18 and the image data storage area in which the digital image data should be stored. The attribute data storage area S corresponding to (S) is set to the data value 2 (step A7). The CPU 14 repeatedly performs the operations of steps A3-A7 until the camera is turned off by the power switch (step A8).

In the above operation, setting data in the attribute data storage area is necessary for initializing the attribute data storage area and then recording the data. However, each attribute data storage area is so small that it does not take much time to initialize and write data to the attribute data storage area.

In this embodiment, since the image data is always stored in the initialized image data storage area, the recording operation time does not change. Further, the erasing operation and the recording operation for the flash memory 18 can be terminated in a relatively short time because the image data storage area is already initialized, that is, it is initialized when the camera is turned on.

3 shows an initialization operation by the CPU 14 in the second embodiment of the present invention.

The CPU 14 detects that the electronic still camera is turned on by the power switch or the recording mode is selected by the mode key (step B1). The CPU 14 reads erased number data from the ROM 15 or the RAM 16. The number of deletions is the maximum number of image data storage areas to be deleted by the initialization operation (step B2). This avoids long waits on power up. The erase count can be stored in the ROM 15 by the manufacturer or in the RAM 16 by the user. In this embodiment, the number of deletions is ten. The CPU 14 sets 1 to the counter N (step B3). The CPU 14 designates the address of the attribute data storage area and the image data storage area of the flash memory 18 based on the counter N. The CPU 14 determines whether each attribute data storage area addressed based on the counter N stores attribute data 1 (step B4). When the attribute data storage area does not store attribute data 1, the CPU 14 increments the counter N by 1 (step B5), and checks whether the counter N exceeds 100 (step B6). When the counter N exceeds 100, the CPU 14 finishes performing the initialization operation. When the counter N does not exceed 100, the CPU 14 performs the operation of step B4 again. In step B4, the CPU 14 checks whether the addressed attribute data storage area contains the attribute data 1, and if it is checked that it is included, then the CPU 14 corresponds to the attribute data storage area storing the attribute data 1 The image data storage area is initialized and the attribute data 1 is replaced with the attribute data 0 in the attribute data storage area (step B7). The CPU 14 increments the deleted number counter DN indicative of the number of initialized image data storage areas by one (step B8). It is determined whether the deleted number counter DN is equal to the deleted number data (step B9, set to 10 in this example). On the other hand, when the deleted number DN is not equal to the deleted number data, the CPU 14 performs steps B5, until the counter N exceeds 100 (step B6) or detects that the deleted number counter DN is equal to the deleted number data. The operations of B6, B4 and B7-B9 are repeatedly performed (step B9).

In this embodiment, the maximum time for which the user recognizes the inoperable time during the initialization operation does not change because the maximum number of image data storage areas to be deleted is fixed.

4 shows an initialization operation by the CPU 14 in the third embodiment of the present invention. Step C2-C9 of the flowchart in FIG. 4 is the same operation as step B2-B9 in FIG. In this embodiment, the CPU 14 starts performing the initialization operation when detecting that the power switch of the key input section 14 is operated from the power on position to the power off position (step C1). That is, the CPU 14 performs the operation of step C2-C9 (same as step B2-B9) after the power switch is turned OFF, and the counter N exceeds 100 (step C6) or the deleted counter counter DN is deleted. The actual OFF of the camera is delayed until it is equal to the numerical data (step C9). In this embodiment, since the initialization operation is performed after the user turns off the camera, the user does not recognize the inoperable time.

5 shows an initialization operation by the CPU 14 in the fourth embodiment of the present invention. Steps D2-D9 in the flowchart of Fig. 5 are the same operations as steps B2-B9 of Fig. 3. In this embodiment, the CPU 14 starts performing the initialization operation when the regeneration mode is selected as the mode key of the key input device 13 (step D1). The CPU 14 changes from the recording mode to the reproduction mode and performs the operations of steps D2-D9 as in steps B2-B9 in FIG.

In this embodiment as well, the user is not aware of the down time.

6 shows an initialization operation by the CPU 14 in the fifth embodiment of the present invention. Step E2-E9 of the flowchart in FIG. 4 is the same operation as step B2-B9 in FIG. In this embodiment, the CPU 14 performs an initialization operation in accordance with steps E3-E10 during the time when the trigger switch is not pressed in the recording mode. That is, the CPU 14 checks whether the trigger switch is pressed for a predetermined time (steps E1 and E2). When not pressed for a predetermined time, the CPU 14 starts to perform the operation of steps E3-E10 as in steps B2-B9 in FIG. When the trigger switch is pressed, the CPU 14 checks the attribute data storage area of the flash memory 18 in which the attribute data 0 is stored (step E11). When the CPU 14 searches the attribute data storage area storing the attribute data 0, the image data corresponding to the image captured by the CCD 1 is stored in the image data storage area of the flash memory 18, which is the attribute data 0. Is designated as an attribute data storage area for storing data (step E17).

When the CPU 14 determines that the attribute data storage area does not store attribute data 0 (step E11), sets the counter N to 1 (step E12), after which the CPU 14 assigns the attribute data designated by the counter N. Examine the attribute data stored in the storage area. The CPU 14 initializes the image data storage area of the flash memory 19 designated as the attribute data storage area for storing the attribute data 1 when detecting the attribute data 1 stored in the attribute data storage area and stores the image data ( Step E17). If the CPU 14 does not detect the attribute data 1 stored in the attribute data storage area designated by the counter N, the counter N is incremented by 1 (step E14) and compared with a predetermined number indicating the number of image data storage areas. (100 in this case) (step E15). The CPU 14 repeatedly performs the operations of steps E13 to E5 until the counter N exceeds 100 (step E14) or the attribute data 1 is detected (step E13).

Fig. 7 shows an initialization operation by the CPU 140 in the sixth embodiment of the present invention. Step F6-F13 in the flowchart in Fig. 7 is the same operation as step B2-B9 in Fig. 3. In this embodiment, the CPU 14 detects which key of the key input device 13 is pressed (F1) When pressing one of the keys of the key input device 13, the CPU 14 resets the counter t (step F2). Perform the operation indicated by the key (step F3) When no key of the key input means 13 is pressed, the CPU 14 increments the counter t by one and compares the counter t with a predetermined number T (step F5). The CPU 14 checks again the key presses of the key input device 13 when the counter does not exceed the predetermined number T (step F1) When the counter t exceeds the predetermined number T, the CPU 14 ) Performs the operations of steps F6-F13 as in steps B2-B9 in FIG. 3.

6 and 7, the initialization operation may be performed while the electronic still camera is not in use. In addition, the initialization operation may be performed periodically.

8 shows an initialization operation by the CPU 14 in the seventh embodiment of the present invention. Steps G1-G13 of the flowchart in FIG. 8 are the same as steps F1-F13 in FIG. In this embodiment the camera has an auto power off function. That is, the camera turns off automatically when no key is pressed for a predetermined time. As shown in Fig. 8, the CPU 14 detects whether a predetermined time has elapsed while no key is pressed (steps G1-G3). When the predetermined time has elapsed, that is, when the counter t exceeds the predetermined number T (step G5), the CPU 14 performs an operation of steps G6-G13 such as steps F6-F13 and turns off the camera (step G14).

According to this embodiment, since the initialization operation is performed while the camera is not in use, the user does not recognize the time to be recognized as an inoperable time.

9 shows an initialization operation by the CPU 14 in the eighth embodiment of the present invention. Steps H8-H13 of the flowchart in FIG. 9 are the same operations as steps B3-B5 and B7-B9 in FIG.

In this embodiment, the electronic still camera has an initialization mode key on the key input device 13 which selects one of all initialization modes and limited initialization modes. In all the initialization modes, all the image data storage areas corresponding to the attribute data storage areas for storing the attribute data 1 are initialized by the initialization operation. On the other hand, in the limited initialization mode, the limited number of storage areas of the image data corresponding to the attribution data storage area storing the attribution data 1 is initialized by the initialization operation. The CPU 14 starts the initialization operation when the electronic still camera is turned on by the power switch or detects that the recording mode is selected by the mode key (step H1). First, the CPU 14 counts the number of attribute data storage areas for storing attribute data 1 (step H2). When the number counted in step H2 is 0, the CPU 14 does not perform an initialization operation (step H3). When the number counted in step H2 is not zero, the CPU 14 detects whether the selected initialization mode is all initialization modes or limited initialization modes (step H4). In all the initialization modes, the CPU 14 sets the counted number of the attribute data storage areas for storing the attribute data 1 as the delete count data (step H5). In the limited initialization mode, the CPU 14 determines whether the counted number of the attribute data storage areas for storing the attribute data is smaller than the predetermined number α (step H6). When the counted number is smaller than the predetermined number α, the CPU 14 sets the counted number of the attribute data storage areas for storing the attribute data 1 as the deleted number data (step H5). When the counted number is not smaller than the predetermined number α, the CPU 14 sets the number obtained by subtracting the predetermined number α from the counted number as erased number data. The CPU 14 then performs the operations of steps H8-H13 such as steps B3-B5 and B7-B9 in FIG.

In this embodiment, the camera user may select an inoperable time at the time the camera is turned on and the recording mode is selected.

Fig. 10 shows an initialization operation by the CPU 14 in the ninth embodiment of the present invention. Steps I5-I11 in the flowchart in Fig. 10 are the same operations as in steps B3-B9 in Fig. 3. In this embodiment, the CPU 14 checks whether the image quality mode is switched between the fine mode and the standard mode (step I1). When the image quality mode changes from the fine mode to the standard mode (step I2), the CPU 14 sets the first predetermined number A as the number of erase data (step I3). On the contrary, when the image quality mode changes from the standard mode to the fine mode (step I2), the CPU 14 sets the second predetermined number B as the number of erase data (step I4). In this embodiment, the first predetermined number A is the second predetermined number A because the image data for the image taken in the fine mode generally requires a larger number of image data storage areas than for the image in the standard mode. Less than B) The numbers A and B can be determined by the calculation as described later. The CPU 14 then performs the operations of steps I5-I11 as in steps B3-B9 in FIG.

11 shows an initialization operation by the CPU 14 in the tenth embodiment of the present invention. Steps J2-J9 of the flowchart in FIG. 11 are the same operations as steps B2-B9 in FIG. In this embodiment, the CPU 14 detects the initialization command from the personal computer connected to the camera via the serial input / output terminal 20 (step J1). When the personal computer supplies the initialization command to the camera, the CPU 14 performs the operations of steps J2-J9 such as steps B2-B9 in FIG.

12 shows an initialization operation by the CPU 14 in the eleventh embodiment of the present invention. Steps K6-K12 in the flowchart in Fig. 12 are the same operations as in steps B3-B9 in Fig. 3. In this embodiment, the CPU 14 detects an average number of image data storage areas storing image data while the recording mode is selected. In the recording mode, the CPU 14 detects whether the trigger switch is pressed (steps K1 and K2). When the trigger switch is pressed, the CPU 14 increments the counter SN by one in the standard mode or by three in the fine mode (step K3). When the camera exits the recording mode, such as when the camera is switched to the playback mode or OFF, the CPU 14 increments the counter RN by one (step K4). In addition, the CPU 14 divides the total number in the counter SN by the total number in the counter RN (step K4) and sets the divided quotient as the deleted data (step K5). The CPU 14 then performs the operations of steps K6-K12 as in steps B2-B9 in FIG. In this embodiment, the camera user can obtain the correct number of initialized image data storage areas in order to provide the necessary initialization operation in the shortest period of time which can be operated.

Fig. 13 shows an initialization operation by the CPU 14 in the twelfth embodiment of the present invention. In this embodiment, the CPU 14 detects the average capacity of the image data storage area storing image data while the recording mode is selected. In the recording mode, the CPU 14 detects whether the trigger switch is pressed (steps L1 and L2). When the trigger switch is pressed, the CPU 14 detects the capacity C of the image data storage area of the flash memory 18 required to store the image data corresponding to the captured image and adds the capacity to the register CN (step L4). ). The CPU 14 increments the counter RN by 1 when the camera exits the recording mode such as being switched to the playback mode or OFF (step L5). In addition, the CPU 14 divides the number added to the register CN by the total number in the counter RN (step L6) and sets the divided quotient as erasing capacity data indicating the maximum capacity of the image data storage area to be deleted during the initialization operation (step L6). L7). Then, the CPU 14 performs the operation of steps L8-L14 similar to the steps B2-B9 in FIG. In this embodiment, the CPU 14 adds the capacity of the initialized image data storage area to the deleted capacity register DC each time the image data storage area is initialized (steps L12 and L13), and the capacity at the deleted capacity register DC. Is compared with the erased capacity data (step L14). When relying on the compressed image content of the compression-decompression device 6, the capacity of the flash memory 18 required to store the compressed image data is different for each image data. This embodiment is therefore particularly effective in electronic still cameras using such compression-decompression devices.

Fig. 14 shows an initialization operation by the CPU 14 in the thirteenth embodiment of the present invention. Steps M6-M12 of the flowchart in Fig. 14 are the same operations as steps L8-L14 in Fig. 13. In this embodiment, the attribute data storage area stores mode attribute data indicating whether image data stored in the image data storage area is processed in a fine or standard mode. When the camera 14 detects that the camera is turned on or the recording mode is selected (step M1), the CPU 14 counts the number of images taken in the fine mode and the standard mode, respectively (step M2). When the number of images taken in the fine mode is larger than in the standard mode (step M3), the CPU 14 sets the capacity A 'as the erase capacity data (step M5). The dose A 'is greater than the dose B'. The CPU 14 then performs the operations of steps M6-M12, such as steps L8-L14 in FIG.

Fig. 15 shows the initialization operation by the CPU 14 in the fourteenth embodiment of the present invention. Steps N2-N12 in the flowchart in FIG. 15 are the same operations as in steps L2-L14 in FIG. In this embodiment, the CPU 14 stores the selected image quality mode (fine or standard mode) in the mode memory register in the ROM 16 when the camera is turned off (steps N1-N3). When the camera is turned on (step N4), the CPU 14 sets the capacity A 'or B' based on the image quality mode stored in the mode memory register as erased capacity data.

Although the embodiments described above illustrate the invention as applied to an electronic still camera, the present invention may be used in an electronic still camera and other various devices. In the above-described embodiments, the attribute data storage area is included in the flash memory, but may also be included in RAM or other suitable memory. In addition, the present invention is not limited to flash memory as other suitable memory technologies may be used as the memory means. The features of each embodiment described above can also be combined with other embodiments.

Claims (37)

Memory means having one or more data storage areas for storing data; Recording means for recording data in a data storage area of the memory means; Operating means for operating said recording means for recording data in a data storage area of said memory means; Deletion instructing means for indicating a data storage area of the memory means for storing deleted data; Detection means for detecting a predetermined time when the operation means does not operate the recording means and during which it is desirable to delete data from the data storage area; And deletion means for deleting the data from the data storage area of the memory means instructed by the deletion instructing means at the predetermined time detected by the detection means. 2. The apparatus of claim 1, further comprising a power switch; The detecting means includes means for detecting that the power switch is operated; And said deleting means comprises means for deleting said data from said data storage area of said memory means instructed by said deleting instruction means at a time when said detecting means detects that said power switch is activated. Data storage. 3. A data storage apparatus as claimed in claim 2, wherein said detecting means comprises means for detecting that a power switch is activated to turn on the device. 4. The data storage apparatus according to claim 3, further comprising limiting means for controlling the deleting means and for limiting the data storage area of the memory means from which the data is deleted by the deleting means to a limited number. . 5. The apparatus according to claim 4, further comprising: data control means for controlling the size of the data stored in the memory means in accordance with the control mode and having at least two control modes; A mode selecting means for selecting one of the control modes of the data control means; And the limiting means includes limiting number determining means for determining the limited number based on the control mode selected by the mode selecting means. 6. The apparatus according to claim 5, further comprising image signal input means for inputting image signal; The data control means having a first control mode and a second control mode First data control means for producing first image data based on the image signal input from the image signal input means in the first control mode; Second data control means for producing second image data having a smaller size than the first image data based on the image signal input from the image signal input means in the second control mode; The memory means includes means for storing the first image data in the first number of the data storage areas and the second image data in the second number of the data storage areas smaller than the first number; The limit number determining means includes means for determining a first limit number when the first control mode is selected and a second limit number smaller than the first limit number when the second control mode is selected. Data storage. 5. The apparatus according to claim 4, further comprising: recording mode means for enabling the data to be written to said memory means; Reading mode means for enabling reading of said data stored in said memory means; Selection means for selecting one of the recording mode means and the read mode means; Calculation means for calculating the average size of the data stored in the memory means for each time the recording mode means is selected by the selection means, And the limiting means includes limiting number determining means for determining the limiting number based on the average size calculated by the calculating means. 5. The data storage apparatus according to claim 4, wherein said limiting means includes limiting number input means for inputting said limiting number. 3. The apparatus according to claim 2, wherein the detecting means includes means for detecting that the power switch is operated to turn off the device, and the off means for turning off the device after the deleting means deletes the data from the memory means. The data storage device further comprises. 10. The data storage according to claim 9, further comprising limiting means for controlling the deleting means and for limiting the data storage area of the memory means from which the data is deleted by the deleting means to a limited number. Device. 11. The apparatus according to claim 10, further comprising: data control means for controlling the size of the data stored in the memory means in accordance with the control mode and having at least two control modes; A mode selecting means for selecting one of the control modes of the data control means; And the limiting means includes limiting number determining means for determining the limiting number based on the control mode selected by the mode selecting means. 12. The apparatus according to claim 11, further comprising image signal input means for inputting image signal; The data control means having the first control mode and the second control mode First data control means for producing first image data based on the image signal input from the image signal input means in the first control mode; Second data control means for producing second image data having a smaller size than the first image data based on the image signal input from the image signal input means in the second control mode; The memory means includes means for storing the first image data in the first number of the data storage areas and the second image data in the second number of the data storage areas smaller than the first number; The limit number determining means includes means for determining a first limit number when the first control mode is selected and a second limit number smaller than the first limit number when the second control mode is selected. Data storage. 11. The apparatus according to claim 10, further comprising: recording mode means for enabling the data to be written to said memory means; Reading mode means for enabling reading of said data stored in said memory means; Selection means for selecting one of the recording mode means and the read mode means; Calculation means for calculating the average size of the data stored in the memory means at each time the recording mode means is selected by the selection means; And the limiting means includes limiting number determining means for determining the limiting number based on the average size calculated by the calculating means. 11. The data storage device according to claim 10, wherein said limiting means includes limiting number input means for inputting said limiting number. 2. The apparatus according to claim 1, wherein said detecting means includes means for detecting a predetermined period of time during which said operating means has not operated said recording means; And said deleting means comprises means for deleting said data from said data storage area of said memory means instructed by said deleting instruction means at a time when said detecting means detects said predetermined period of time. . 2. The apparatus of claim 1, further comprising a key input device; The detecting means includes means for detecting a predetermined period of time during which the key input device is not operated; And said deleting means comprises means for deleting said data from said data storage area of said memory means instructed by said deleting instruction means at a time when said detecting means detects said predetermined period of time. . 17. The data storage apparatus according to claim 16, wherein said deleting means further comprises an off means for turning off said apparatus after deleting said data from said memory means. The recording medium according to claim 1, further comprising: recording mode means for enabling the data to be recorded in the memory means; Reading mode means for enabling reading of said data stored in said memory means; Selecting means for selecting one of the recording mode means and the read mode means; The detecting means includes means for detecting that the selecting means selects the recording mode means; The erasing means includes means for deleting the data in the data storage area of the memory means instructed by the erasing indicating means at a time when the detecting means detects that the selecting means detects the recording mode means. And a data storage device. The apparatus of claim 1, further comprising connecting means for connecting to a peripheral device; The detecting means comprises means for detecting a command from the peripheral device via the connecting means; The deleting means is for deleting the data in the data storage area of the memory means instructed by the deletion instructing means at a time when the detecting means detects that the selection means detects the command from the peripheral device. And a means for storing the data. 2. The apparatus of claim 1, further comprising: data control means for controlling the size of said data stored in said memory means in accordance with said control mode; A mode selecting means for selecting one of the control modes of the data control means; The detecting means includes means for detecting that the mode selecting means selects one of the control modes of the data control means; The erasing means includes means for deleting the data in the data storage area of the memory means instructed by the erasing indicating means at a time when the detecting means detects that the selecting means detects the recording mode means. And a data storage device. 2. The apparatus according to claim 1, further comprising attribute data storage means for storing deletion instruction data for the data storage region indicated by the deletion instruction region; And said deleting means includes means for deleting said data stored in said data storage area based on said attribute data storage means. Memory means for storing a plurality of data sets; Recording means for recording the data set in the memory means; Actuating means for actuating said recording means for recording said data set in said memory means; Deletion instructing means for indicating the data set to be deleted from the memory means; Detection means for detecting a predetermined time while the operation means does not operate the recording means; And deletion means for deleting the data set indicated by the deletion instructing means from the memory means at a predetermined time detected by the detection means. 23. The apparatus of claim 22, further comprising a power switch; The detecting means includes means for detecting that the power switch is operated; And said deleting means includes means for deleting said data set indicated by said deleting instruction means from said memory means at a time when said detecting means detects that a power switch is activated. 24. The data storage apparatus according to claim 23, wherein said detecting means comprises means for detecting that said power switch is operated to turn on said device. 24. The data storage apparatus as claimed in claim 23, further comprising limiting means for controlling said deleting means and for limiting said data set deleted from said memory means by said deleting means. 24. The apparatus of claim 23, further comprising: data control means for controlling the size of the data stored in the memory means in accordance with the control mode and having at least two control modes; A mode selecting means for selecting one of the control modes of the data control means; Limiting means for controlling said deleting means and for limiting said data set deleted from said memory means by said deleting means to a limit size determined based on said control mode selected by said mode selecting means. Data storage. The detecting means includes means for detecting that the mode selecting means selects one of the control modes of the data control means; The deleting means includes means for deleting the data from the data storage area of the memory means instructed by the deletion instructing means at a time when the detecting means detects that the selection means detects the recording mode means. And a data storage device. 27. The apparatus according to claim 26, further comprising image signal input means for inputting image signal; The data control means having a first control mode and a second control mode First data control means for producing a first set of image data based on the image signal input from the image signal input means in the first control mode; Second data control means for producing second set image data having a smaller size than the first image data based on the image signal input from the image signal input means in the second control mode; The memory means includes means for storing the first set image data in the first number of the data storage areas and the second set image data in the second number of the data storage areas smaller than the first number; ; The limiting means comprises means for determining a first limiting size when the first control mode is selected and a second limiting size smaller than the first limiting size when the second control mode is selected. Data storage device. 24. The apparatus according to claim 23, further comprising: recording mode means for enabling the recording of said data in said storage means; Reading mode means for enabling reading of said data stored in said memory means; Selection means for selecting one of the recording mode means and the read mode means; Calculation means for calculating the average size of the data stored in the memory means for each time the recording mode means is selected by the selection means; And the limiting means includes limiting number determining means for determining the limiting number based on the average size calculated by the calculating means. 24. The data storage as claimed in claim 23, further comprising limiting means for controlling the deleting means and for limiting the data storage area of the memory means from which the data is deleted by the deleting means to a limited number. Device. 24. The apparatus according to claim 23, wherein said detecting means comprises means for detecting that said power switch is activated to turn off said device and said turning off means for turning off said device after said deleting means deletes said data from said memory means. The data storage device further comprises. 23. The apparatus according to claim 22, wherein said detecting means includes means for detecting a predetermined period of time during which said operating means has not operated said recording means; And means for deleting the data set indicated by the delete instructing means from the memory means at a time when the detecting means detects the predetermined period of time. 23. The apparatus of claim 22, further comprising a key input device; The detecting means includes means for detecting a predetermined period of time during which the key input device is not operated; And said deleting means comprises means for deleting said data set indicated by said deleting instruction means from said memory means at a time when said detecting means detects said predetermined period of time. 33. The data storage apparatus according to claim 32, further comprising an off means for turning off the device after the deleting means deletes the data set from the memory means. 23. The apparatus of claim 22, further comprising: recording mode means for enabling the data to be written to the memory means; Reading mode means for enabling reading of said data stored in said memory means; Selecting means for selecting one of the recording mode means and the read mode means; The detecting means includes means for detecting that the selecting means selects the recording mode means; The deleting means includes means for deleting the data from the data storage area of the memory means instructed by the deletion instructing means at a time when the detecting means detects that the selection means detects the recording mode means. And a data storage device. 23. The apparatus of claim 22, further comprising connecting means for connecting to a peripheral device; The detecting means comprises means for detecting a command from the peripheral device via the connecting means; The deleting means is for deleting the data in the data storage area of the memory means instructed by the deletion instructing means at a time when the detecting means detects that the selection means detects the command from the peripheral device. And a means for storing the data. 23. The apparatus according to claim 22, further comprising: data control means for controlling the size of the data stored in the memory means in accordance with the control mode and having at least two control modes; A mode selecting means for selecting one of the control modes of the data control means; The detecting means includes means for detecting that the mode selecting means selects one of the control modes of the data control means; The erasing means includes means for deleting the data in the data storage area of the memory means instructed by the erasing indicating means at a time when the detecting means detects that the selecting means detects the recording mode means. And a data storage device. 23. The apparatus according to claim 22, further comprising attribute data storage means for storing deletion instruction data for the data storage region indicated by the deletion instruction region; And said deleting means includes means for deleting said data stored in said data storage area based on said attribute data storage means.